Microfluidic analysis cartridge

Abstract
A device for analyzing sample solutions such as whole blood based on coagulation and agglutination which requires no external power source or moving parts to perform the analysis. Single disposable cartridges for performing blood typing assays can be constructed using this technology.
Description




BACKGROUND OF THE INVENTION




1. Field of the Invention




The present invention relates generally to devices and methods for analyzing samples in microfluidic cartridges, and, in particular, to a device for analyzing sample solutions such as whole blood based on coagulation and agglutination which requires no external power source or moving parts.




2. Description of the Related Art




Microfluidic devices have recently become popular for performing analytical testing. Using tools developed by the semiconductor industry to miniaturize electronics, it has become possible to fabricate intricate fluid systems which can be inexpensively mass produced. Systems have been developed to perform a variety of analytical techniques for the acquisition of information for the medical field.




In microfluidic channels, fluids usually exhibit laminar behavior. U.S. Pat. No. 5,716,852, which patent is herein incorporated by reference in its entirety, is an example of such a device. This patent teaches a microfluidic system for detecting the presence of analyte particles in a sample stream using a laminar flow channel having at least two input channels which provide an indicator stream and a sample stream, where the laminar flow channel has a depth sufficiently small to allow laminar flow of the streams and length sufficient to allow diffusion of particles of the analyte into the indicator stream to form a detection area, and having an outlet out of the channel to form a single mixed stream. This device, which is known as a T-Sensor, allows the movement of different fluidic layers next to each other within a channel without mixing other than by diffusion. A sample stream, such as whole blood, and a receptor stream, such as an indicator solution, and a reference stream, which is a known analyte standard, are introduced into a common microfluidic channel within the T-Sensor, and the streams flow next to each other until they exit the channel. Smaller particles, such as ions or small proteins, diffuse rapidly across the fluid boundaries, whereas larger molecules diffuse more slowly. Large particles, such as blood cells, show no significant diffusion within the time the two flow streams are in contact.




Two interface zones are formed within the microfluidic channel between the fluid layers. The ratio of a detectable property, such as fluorescence intensity, of the two interface zones is a function of the concentration of the analyte, and is largely free from cross-sensitivities to other sample components and instrument parameters.




Usually, microfluidic systems require some type of external fluidic driver to function, such as piezoelectric pumps, micro-syringe pumps, electroosmotic pumps, and the like. In U.S. patent application Ser. No. 09/415,404, which application is assigned to the assignee of the present invention and is hereby incorporated by reference, microfluidic systems are described which are totally driven by inherently available internal forces such as gravity, capillary action, absorption by porous material, chemically induced pressures or vacuums, or by vacuum or pressure generated by simple manual action upon a power source located within the cartridge. Such devices are extremely simple and inexpensive to manufacture and do not require electricity or any other external power source for operation. Such devices can be manufactured entirely out of a simple material such as plastic, using standard processes like injection molding or laminations. In addition, microfluidic devices of this type are very simple to operate.




microfluidic devices of this type described can be used to qualitatively or semi-quantitatively determine analyte concentrations, to separate components from particulate-laden samples such as whole blood, or to manufacture small quantities of chemicals.




A practical use of these microfluidic devices could be in the determination of several parameters directly in whole blood. A color change in the diffusion zone of a T-Sensor detection channel can provide qualitative information about the presence of the analyte. This method can be made semi-quantitative by providing a comparator color chart with which to compare the color of the diffusion zone, similar to using a paper test strip, but with greate control and reproducibility.




It would be desirable, in many situations, to produce a device for analyzing samples in microfluidic channels based on coagulation or agglutination as a function of contact between sample analyte particles and reagent particles. An example of such an assay would be the determination of a person's blood group by bringing a drop of blood into contact with one or more antisera on a disposable microfluidic cartridge, and visually observing the flow behavior of these two solutions as they flow adjacent to each other, or mixed through sedimentation as they flow with each other through microfluidic channels. If a reaction occurs, the flow will either slow down, stop, or show another observable change that can be attributed to coagulation or agglutination.




The accuracy of the device can be enhanced by the addition of a readout system which may consist of an absorbance, fluorescence, chemiluminescence, light scatter, or turbidity detector placed such that the detector can observe an optically observable change caused by the presence or absence of a sample analyte or particle in the detection channel. Alternatively, electrodes can be placed within the device to observe electrochemically observable changes caused by the presence or absence of a sample analyte or particle within the detection channel.




SUMMARY OF THE INVENTION




Accordingly, it is an object of the present invention to provide a microfluidic device which is capable of performing diagnostic assays without the use of an external power source.




It is a further object of the present invention to provide a disposable cartridge for analyzing fluid samples which is inexpensive to produce and simple to operate.




It is another object of the present invention to provide a microfluidic analysis cartridge in which a visual analysis can be made of the sample reaction.




These and other objects are accomplished in the present invention by a simple cartridge device containing microfluidic channels which perform a variety of analytical techniques based on coagulation or agglutination without the use of external driving forces applied to the cartridge. Single disposable cartridges for performing blood typing assays can be constructed using this technology.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a plan view of a microfluidic cartridge used for performing blood typing according to the present invention;





FIG. 2

is a plan view depicting an alternative embodiment of a microfluidic cartridge for performing blood typing according to the present invention;





FIG. 3

is a side view of the cartridge of

FIG. 2

;





FIGS. 4A-C

show a series of microfluidic cartridges according to

FIG. 2

within which a diagnostic test for blood typing has been performed;





FIGS. 5A and B

are additional views of

FIGS. 4C and 4B

, respectively, at the conclusion of the diagnostic test;





FIG. 6

is a plan view of another alternative embodiment of the microfluidic cartridge of

FIG. 2

;





FIG. 7

is a plan view of another embodiment of the microfluidic cartridge of

FIG. 2

; and





FIG. 8

is a view of a device holding microfluidic cartridges constructed according to the present invention at a constant angle.











DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS




The pressure required to drive a blood sample through a microfluidic channel at a specified volume flow rate is determined by the equation:








Hc=RQ/ρg








where Hc is the head pressure, R is the fluid resistance within the channel, Q is the volume flow rate, ρ is the density of the liquid, and g is the acceleration of gravity.




The fluid resistance R can be calculated using the equation:








R=


128μ


L/


4


AF




AR




D




H








where μ is the dynamic viscosity of the fluid, L is the length of the channel, F


AR


is the aspect ratio (ratio of length vs. width) of the channel, D


H


is the hydraulic diameter of the channel, and A is the cross-sectional flow area of the channel. The characteristic dimension of a cross-sectional flow area A of a channel is the hydraulic diameter D


H


. For a circular pipe, D


H


is the pipe diameter; for a rectangular channel, D


H


is four times the area divided by the wetted perimeter, or:








D




H


=2/(1


w+


1/


h


)






where h and w are the channel cross-sectional dimensions. In the present invention, microfluidic channels are fluid passages or chambers which have at least one internal cross-sectional dimension that is less than 500 μm, and typically between about 0.1 μm and 250 μm.




The aspect ratio F


AR


represents the modification of resistance to flow in the rectangular channel due to the aspect ratio of the cross-sectional flow area. For example, two channels with the same flow area have markedly different resistance to flow if one has a square cross section and the other is very thin but wide. To allow the use of a single formula for resistance, F


AR


=1 for a circular pipe. A formula for approximating the aspect ratio within 2% for a rectangular channel has been developed:








F




AR


=2/3 +11


h


(2-


h/w


)/24


w








where h is less than w.




As an example, using these formulas to determine the pressure head H


c


required to drive blood (which has a viscosity of 3.6 times the viscosity of water), and using the following parameters:




Q=0.2 μl/sec




h=250 μm




w=1000 μm




L=200 mm




g=9.81 m/s


2






p=1000 kg/m3




μ3.6×10


−3


Pa s




then F


AR


=0.867, D


H


=400 μm, R=6.642 ×10


11


Pa s/m


3


, and the pressure head Hc required to drive blood through this microfluidic channel is calculated to be 13.5 mm.




Referring now to

FIG. 1

, there is shown a cartridge generally indicated at


10


containing the elements of the present invention. Cartridge


10


is preferably constructed from a single material, such as a transparent plastic, using a method such as injection molding or laminations, and is approximately the size and thickness of a typical credit card. Located within cartridge


10


are a series of microfluidic channels


12


,


14


,


16


. Each of channels


12


,


14


,


16


are individually connected at one end to a circular inlet port


18


,


20


,


22


respectively, each of which couples channels


12


,


14


,


16


to atmosphere outside cartridge


10


. The opposite ends of channels


12


,


14


,


16


all terminate in a circular chamber


24


under a flexible membrane


26


within cartridge


10


, which preferably comprises an aspiration bubble pump. Chamber


24


may also contain a vent


28


which couples its interior to the outside of cartridge


10


.




The operation of cartridge


10


can now be described. A sample, such as whole blood, is divided into three parts, to which different reagents are mixed. In the present embodiment, the blood is combined with a physiologic saline, Anti-A antisera, and Anti-B antisera and a drop of each is place on inlet ports


18


,


20


,


22


separately. Alternatively; a drop of blood from the sample is placed on ports


18


,


20


,


22


, followed by a drop of different reagent for performing the assay, then mixed in the port by conventional means, such as a pipette.




The mixture is drawn into channels


12


,


14


,


16


via ports


18


,


20


,


22


respectively by capillary action, as the channels are sized to create capillary force action and draw the mixtures toward chamber


24


. A reaction of the sample and reagent, such as coagulation, agglutination, or a change in viscosity, is observed within channels


12


,


14


,


16


as the fluids travel toward chamber


24


.




Chamber


24


can be used for waste storage of the fluids after the assay is complete, and aspiration pump


26


can also assist in driving the fluids through the system.





FIG. 2

is directed to an alternative embodiment of the present invention. A microfluidic cartridge


10




a


, manufactured in a similar manner to cartridge


10


of

FIG. 1

, contains a pair of inlet ports


30


,


32


, which connect to a reaction channel


34


via inlet channels


36


,


38


respectively. Inlets


36


,


38


are arranged such that they connect to channel


34


with the one above the other, such that laminar flow in channel


34


is created as shown in

FIG. 3. A

pair of storage chambers


40


,


42


are positioned at the end of channel


34


which act as waste storage receptacles.




The driving force necessary to perform assays within cartridge


10




a


is provided by gravity. This force can be enhanced by spinning the cartridge in a centrifuge. As an example, an assay to determine blood type of a specimen sample can be performed as follows: a droplet


50


of whole blood to be typed is placed on inlet port


32


, while a suitable reagent solution droplet


52


is placed upon inlet port


30


. Cartridge


10




a


is then positioned at an angle to the vertical plane, allowing fluids


50


,


52


to flow into channel


34


. As blood drop


50


flows through inlet


38


into channel


34


, it flows in the upper section of channel


34


, while reagent droplet


52


flows through inlet


36


and enters channel


34


flowing in the lower section of channel


34


, with the two fluids exhibiting laminar flow, as can be clearly seen in FIG.


3


.





FIG. 8

shows a device


53


which holds the cartridges at a constant angle during the assay. The angle at which the cartridge is held may be varied from vertical to horizontal. The speed of the reaction varies according to the angle. As red blood cells settle under normal gravity at the rate of 1 μm/sec., they will, after some time, settle from fluid


50


across the flow boundary into fluid


52


, and begin to react with the antiserum in the reagent solution.




In the instances where the antisera in the reagent solution react with the whole blood in the specimen sample, agglutination will occur, causing a visually observable reaction which indicates the blood type of the sample. A series of channels


55


with graduated width dimensions allow agglutinated particles to travel along according to size.





FIGS. 4A-C

show a blood typing assay performed on a series of cartridges of the design taught in FIG.


2


. Referring now to these figures, cartridges


10




b


,


10




c


,


10




d


show a blood typing experiment in which a blood sample listed as A-positive from the supplier is assayed. Cartridge


10




b


has whole blood placed in inlet


30


and a physiologic saline solution in inlet


32


, cartridge


10




c


has blood from the same source placed in inlet


30


and Anti-A antisera placed in inlet


32


, while cartridge


10


had a blood sample from the same source placed in inlet


30


and Anti-B antisera placed in inlet


32


.




As each of the samples traveled through channel


34


, driven by hydrostatic pressure, the fluids in cartridges


10




b


and


10




d


did not indicate a positive reaction, while the fluid within channel


34


of cartridge


10




c


is showing signs of agglutination, which can be visually detected within channel


34


, indicating a positive reaction for A-positive blood. Views of the completed tests performed within cartridges


10




b


and


10




c


can be more clearly seen in

FIGS. 5A-B

.




An alternative embodiment having a blood typing device integrated into a single cartridge is shown in FIG.


6


. Referring now to

FIG. 6

, a cartridge


10




e


contains a first chamber


60


which is coupled to a port


62


, and is also connected to a series of microfluidic channels


64


,


66


,


68


,


69


. Channel


64


terminates in a chamber


70


, channel


66


terminates in a chamber


72


, while channel


68


terminates in a chamber


74


. Each of chambers


70


,


72


,


74


are connected to another chamber


76


via passageways


78


,


80


,


82


respectively. Passageways


78


,


80


,


82


each have a section containing a fine grating


78




a


,


80




a


,


82




a


respectively. Chamber


76


is also coupled to atmosphere outside of cartridge


10




e


via a port


84


. Channel


69


couples chamber


60


to another chamber


90


, which is coupled to the exterior of cartridge


10




e


by a port


92


.




To perform a blood typing assay with this device, a diluent


94


is pre-inserted into chamber


60


, while chambers


70


,


72


,


74


are pre-filled with reagents


96


,


98


,


100


for detection blood types A, B and O respectively. After these preliminary steps have been taken, ports


62


,


84


, and


92


are sealed, preferably by covering with tape.




The analysis begins by removing the seal from port


62


, and inserting a quantity of blood of an unknown type into port


62


with a syringe or pipette dropper, which sample enters chamber


60


containing diluent


94


. Port


62


is then resealed, and cartridge


10




e


is shaken, allowing the blood cells to mix with diluent


94


. The cells are then allowed to sediment, positioning cartridge


10




e


in the orientation shown in FIG.


6


. After sedimentation, ports


62


and


92


are unsealed, which allows excess diluent


94


to travel via channel


69


into chamber


90


. Next, port


84


is unsealed, allowing the diluted blood sample to flow into chambers


70


,


72


,


74


via channels


64


,


66


,


68


respectively, where it can mix with reagents


96


,


98


,


100


. Cartridge


10




e


is then shaken briefly, and placed in a temperature-controlled environment in the orientation shown in

FIG. 6

for ten minutes.




After the specified time period has elapsed, cartridge is taken from the controlled environment, and rotated 90° in the direction shown by arrow A, placing chamber


76


at the lowermost position in cartridge


10




e


. This allows the mixed solutions in chambers


70


,


72


,


74


to flow toward chamber


76


via passageways


78


,


80


,


82


respectively.




As the solutions reach fine gratings


78




a


,


80




a


,


82




a


, the cells in the chamber which contained the reagent of the unknown blood type will begin to agglutinate, causing a blockage within that particular channel, causing a visual representation of the particular blood type, as the chamber relative to that blood type has not emptied, due to clogging. Cartridge


10




e


can now be safely discarded, with ports


62


,


84


,


92


resealed with tape or the like to retain all fluids within the cartridge. This cartridge design is desirable, as it allows the washing of the blood cells to be analyzed prior to their contact with the antisera.




An alternative embodiment of a blood typing device (similar to that shown in

FIG. 6

) can be seen in FIG.


7


. Referring now to

FIG. 7

, a cartridge


10




f


contains a first chamber


110


which is coupled to the exterior of the cartridge by a port


112


. Chamber


110


is connected to a chamber


114


via a microfluidic channel


116


. Chamber


114


contains a port


118


which couples chamber


114


to the exterior of cartridge


10




f


. Port


118


is initially blocked by a plug


120


.




Chamber


110


is also connected to a chamber


122


by a channel


124


. Chamber


110


is connected to a chamber


126


by a channel


128


, while chamber


128


is connected to a chamber


130


via a series of parallel channels


132


. Finally, chamber


130


is coupled to the exterior of cartridge


10




f


through a port


134


, which is initially blocked by a plug


136


.




To perform an assay using cartridge


10




f


, plug


136


is removed from port


134


, and an antisera for a particular blood type is added to cartridge


10




f


through port


112


. This fluid, preferably in the amount of 100 μl, flows through chamber


110


and channel


124


into chamber


122


. Plug


136


is then replaced into port


134


.




Next, a blood wash reagent is placed into chamber


110


via port


112


, followed by a sample of blood of unknown type. These fluids are mixed within chamber


110


by shaking, then allowed to settle.




After the mixture in chamber


110


has settled, plug


120


is removed from port


118


in chamber


114


, and cartridge


10




f


is carefully tilted such that the supernatant contained within chamber


110


can be removed from cartridge


10




f


through port


118


. When the process is completed, plug


136


is removed from port


134


, which allows the washed cells contained within chamber


110


to flow through channel


124


into chamber


122


, which already contains antisera solution. The fluids are now mixed with chamber


122


by shaking, and cartridge


10




f


is then incubated for a period of time.




After incubation, cartridge


10




f


is rotated 90° in the direction shown by arrow B, causing the contents of chamber


122


to flow through channel


128


into chamber


126


. If the unknown blood sample reacts with the antisera inserted into cartridge


10




f


, agglutination will clog channel


132


, and chamber


130


will remain empty. If the antisera do not react with the blood sample, chamber will contain fluid from chamber


122


.




While the present invention has been shown and described in terms of several preferred embodiments thereof, it will be understood that this invention is not limited to an particular embodiment and that many changes and modifications may be made without deporting from the true spirit and scope of the invention as defined in the appended claims.



Claims
  • 1. A microfluidic device for analyzing fluids, comprising:a body structure; means located within said body structure for introduction of a sample fluid and a reagent fluid; a flow channel having a first end, coupled to said introduction means, and a second end, for allowing flowing contact between said sample fluid and said reagent fluid along said flow channel such that a reaction between said fluids can occur, with said reaction causing formation of particles within said flow channel into visibly detectable clusters; and separation means, coupled to said second end of said flow channel, having varying dimensions to separate particle clusters of differing sizes.
  • 2. The device of claim 1, wherein said sample fluid and said reagent fluid are introduced into said channel such that each forms a fluid layer contiguously flowing in parallel.
  • 3. The device of claim 2, wherein said flowing layers are oriented such that one layer flows above the other layer, whereby allowing particles to settle from said upper layer to said lower layer.
  • 4. The device of claim 3, wherein particles settling from said upper fluid layer combine with particles in said lower layer to cause a detectable reaction within said channel.
  • 5. The device of claim 1, further comprising means for moving said fluids from said introduction means through said device wherein said fluid moving means requires no electrical or mechanical fluid driver.
  • 6. The device of claim 5, wherein said fluid moving means is selected from the group consisting of: hydrostatic pressure, capillary action, fluid absorption, gravity, and vacuum.
  • 7. The device of claim 1, wherein said flowing channel comprises a transparent channel.
  • 8. The device of claim 7, wherein said transparent flow channel has microfluidic dimensions.
  • 9. The device of claim 1, wherein said clusters are formed by agglutination.
  • 10. The device of claim 1, wherein said clusters are formed by coagulation.
  • 11. A microfluidic device for analyzing blood, comprising:a body structure; means located within said body structure for introduction of a whole blood sample and a reagent sample; a whole blood sample; a reagent sample containing a specific blood type antiserum; and a flow channel having a first end, coupled to said introduction means, and a second end, for allowing flowing contact between said whole blood sample and said reagent sample along said flow channel such that a reaction between said samples can occur, with said reaction causing formation within said flow channel of visibly detectable clusters; wherein the presence of visibly detectable clusters within said flow channel indicates that the blood type of said blood sample matches the specific blood type antiserum within said reagent sample.
  • 12. The device of claim 11, wherein said whole blood sample and reagent sample are introduced into said channel such that each forms a fluid layer contiguously flowing in parallel.
  • 13. The device of claim 12, wherein said flowing layers are oriented such that one layer flows above the other layer, whereby allowing particles to settle from said upper layer to said lower layer.
  • 14. The device of claim 13, wherein said whole blood sample stream flows above said reagent sample stream.
  • 15. The device of claim 14, wherein said formed detectable clusters clog said flow channel to inhibit flow.
CROSS-REFERENCE TO RELATED APPLICATION

This patent application takes priority from U.S. Provisional Application Serial No. 60/189,163, filed Mar. 14, 2000, which application is incorporated herein in its entirety by reference.:

US Referenced Citations (9)
Number Name Date Kind
5225163 Andrews Jul 1993 A
5702953 Mazurek Dec 1997 A
5716852 Yager Feb 1998 A
5922210 Brody Jul 1999 A
5932100 Yager Aug 1999 A
5972710 Weigl et al. Oct 1999 A
5974867 Forster Nov 1999 A
6007775 Yager Dec 1999 A
6297061 Wu Oct 2001 B1
Foreign Referenced Citations (2)
Number Date Country
WO9009596 Dec 1997 WO
WO0022436 Apr 2000 WO
Provisional Applications (1)
Number Date Country
60/189163 Mar 2000 US